JPH1117574A - Double conversion tuner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow a tuner to be used even for a digital system cable television(CATV) sufficiently satisfactorily by reducing reception disturbance produced by a 2nd frequency conversion circuit, especially disturbance by an image signal. SOLUTION: The tuner is provided with a 1st frequency conversion circuit 3 that converts a frequency of a reception signal into a 1st intermediate frequency signal and a 2nd frequency conversion circuit 9 that converts the frequency of the 1st intermediate frequency signal into a 2nd intermediate frequency signal, a trap circuit 8 is provided between the 1st frequency conversion circuit 3 and the 2nd frequency conversion circuit 9 and the trap circuit 8 attenuates an image signal with respect to the 1st intermediate frequency signal.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the reception of digitally processed CATV (cable television) signals.
Alternatively, the present invention relates to a double conversion tuner suitable for receiving a DTV (high definition television) signal.

[0002]

2. Description of the Related Art A conventional general double conversion tuner will be described with reference to the block diagram of FIG. Input terminal 2
The television signal such as CATV or DTV input to 1 is input to the first frequency conversion circuit 23 through a band-pass filter 22 having a band of approximately 54 MHz to 860 MHz. Usually, bandpass filter 2
A low-noise broadband amplifier circuit is provided between the second frequency conversion circuit 23 and the first frequency conversion circuit 23, but is omitted in FIG.
The first frequency conversion circuit 23 has a first mixing circuit 24 and a first local oscillation circuit 25, and the television signal from the band-pass filter 22 is supplied to the first mixing circuit 24.
Is input to Accordingly, television signals of a large number of channels in a band of approximately 54 MHz to 860 MHz are input to the first mixing circuit 24.

In the first frequency conversion circuit 23, the television signal and the first local oscillation signal from the first local oscillation circuit 25 are mixed in a first mixing circuit, so that the frequency of the signals is mixed. A first intermediate frequency signal having a frequency corresponding to the difference is output. Here, as described above, since a large number of television signals are input to the first mixing circuit 24, interference signals due to intermodulation are likely to occur. For this reason, a double balance (double balance) mixer is usually used in the first mixing circuit.

Then, only the desired one-channel television signal IF1 is extracted from the first intermediate frequency signal by the band-pass filter 26 and input to the second frequency conversion circuit 27. Therefore, the band-pass filter 26 has a pass band of 6 MHz, and its center frequency is set to 1 GHz or more. Further, since the band-pass filter 26 has a high passing frequency, it cannot be formed of a tuning circuit using a so-called coil or capacitor, but is formed of, for example, a helical resonator.

The second frequency conversion circuit 27 has a second mixing circuit 28 and a second local oscillation circuit 29. The one-channel television signal IF1 from the band-pass filter 26 is supplied to the second frequency conversion circuit 27. The signal is input to the mixing circuit 28. In the second frequency conversion circuit 27, the one-channel television signal IF1 from the band-pass filter 26 and the second local oscillation signal from the second local oscillation circuit 29 are mixed in the second mixing circuit. As a result, a second intermediate frequency signal IF2 having a frequency corresponding to the difference between the frequencies of these signals is output. The second intermediate frequency signal IF2 is set by the oscillation frequency of the second local oscillation circuit such that the frequency becomes the same as the intermediate frequency signal in a normal television (for example, the band is 41 MHz to 47 MHz in the U.S. specification). . Accordingly, the oscillation frequency of the second local oscillation circuit is approximately 44 MHz with respect to the frequency of the first intermediate frequency signal IF1.
It becomes a low frequency.

[0006]

SUMMARY OF THE INVENTION Conventional double converter
In the John Tuner, the bandpass filter for passing the first intermediate frequency signal is constituted by a helical resonator or the like. Therefore, the attenuation characteristic of the pass band is slow, and the bandpass filter in the second frequency conversion circuit is adjacent. It was susceptible to interference from the channel and the image signal. For this reason, in particular, when receiving a digital CATV or DTV television, there is a problem in that the image quality due to interference is significantly reduced. Further, the transmission loss in the pass band is large, which results in a shortage of gain, resulting in a decrease in reception sensitivity and a deterioration in NF.

Therefore, the double conversion tuner according to the present invention is designed so that the reception disturbance generated in the second frequency conversion circuit can be prevented.
In particular, the interference by the image signal is reduced, and the digital CATV can be used sufficiently satisfactorily.

[0009]

In order to solve the above problems, a double conversion tuner according to the present invention comprises a first frequency conversion circuit for converting a received signal into a first intermediate frequency signal; With a second frequency conversion circuit that frequency-converts the first intermediate frequency signal into a second intermediate frequency signal,
A trap circuit is provided between the first frequency conversion circuit and the second frequency conversion circuit, and the trap circuit attenuates an image signal corresponding to the first intermediate frequency signal.

Further, the double conversion tuner of the present invention provides a desired signal from the first intermediate frequency signal between the first frequency conversion circuit and the second frequency conversion circuit. A passing band-pass filter is inserted in series with the trap circuit, and an amplifying circuit is provided between the trap circuit and the band-pass filter. The trap circuit is constituted by a series resonance circuit of an inductor and a capacitor.

In the double conversion tuner of the present invention, the trap circuit is provided between the amplifier circuit and the second frequency conversion circuit.

Further, in the double conversion tuner of the present invention, the band pass filter is constituted by a dielectric band pass filter comprising a dielectric resonator.

Further, in the double conversion tuner of the present invention, the inductance of the inductor is approximately 10 nanohenries or more.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A double conversion tuner according to the present invention will be described with reference to FIGS. First, FIG.
In FIG. 2, a television signal (received signal) such as CATV or DTV input to the input terminal 1 is approximately 5
The signal passes through a bandpass filter 2 having a band of 4 MHz to 860 MHz and is input to a first frequency conversion circuit 3. Normally, a low-noise broadband amplifier circuit is provided between the bandpass filter 2 and the first frequency conversion circuit 3, but is omitted in FIG. First frequency conversion circuit 3
Has a first mixing circuit 4 and a first local oscillation circuit 5, and a television signal from the band-pass filter 2 is input to the first mixing circuit 4. Therefore, television signals of a large number of channels in a band of approximately 54 MHz to 860 MHz are input to the first mixing circuit 4 (see RF in FIG. 2).

In the first frequency conversion circuit 3, the television signal and the first local oscillation signal from the first local oscillation circuit 5 are mixed in the first mixing circuit 4, whereby the signals are mixed. A first intermediate frequency signal having a frequency corresponding to the frequency difference is output. Here, as described above, since a large number of television signals are input to the first mixing circuit 4, interference signals due to intermodulation are likely to occur. Therefore, the first mixing circuit 4 usually uses a double-balanced mixer.

Then, only the desired one-channel television signal IF1 is extracted from the first intermediate frequency signal through the band-pass filter 6. for that reason,
To change the desired channel, the first local oscillator 5
Will change the oscillation frequency. Therefore, the first local oscillation circuit 5 becomes a variable frequency oscillation circuit. Here, the band pass filter 6 has a pass band of 6 MHz,
Also, its center frequency is 1 GHz or more, more precisely 130
It is set to 1.5 MHz (see IF1 in FIG. 2).
Therefore, for example, when receiving a television signal of channel 2 in the U.S. specification, the first local oscillation circuit 5
Becomes 1358.5 MHz, and 57 MHz which is the center frequency of the band of channel 2 (54 MHz to 60 MHz) is converted to 1301.5 MHz. When receiving another channel, the oscillation frequency of the first local oscillation circuit 5 changes at the oscillation frequency corresponding to that channel (see LO1 in FIG. 2).

As the band-pass filter 6, a dielectric filter composed of a dielectric resonator is used. The dielectric filter has a steep selectivity characteristic, so that the level of a television signal of a channel other than a desired channel including an adjacent channel can be greatly attenuated. The intermediate frequency signal IF1 output from the band pass filter 6 is appropriately amplified by a first intermediate frequency amplifier circuit (amplifier circuit) 7, and then input to a second frequency conversion circuit 9 via a trap circuit 8.

The second frequency conversion circuit 9 has a second mixing circuit 10 and a second local oscillation circuit 11, and the first intermediate frequency signal IF1 from the amplification circuit 7 is supplied to the second mixing circuit 10. Input to the circuit 10. In the second frequency conversion circuit 9, the first intermediate frequency signal IF <b> 1 and the second local oscillation signal from the second local oscillation circuit 11 are mixed in the second mixing circuit 10, so that these signals are mixed. A second intermediate frequency signal IF2 having a frequency corresponding to the difference between the two frequencies is output. The second intermediate frequency signal IF2 is set by the oscillation frequency of the second local oscillation circuit 11 so that the frequency becomes the same as the intermediate frequency signal in a normal television (for example, the band is 41 MHz to 47 MHz in the US specification). You. Therefore, the oscillation frequency of the second local oscillation circuit 11 is fixed, and the center frequency of the first intermediate frequency signal IF1,
1301.5 which is the center frequency of the band-pass filter 6
1257, which is 44 MHz lower than the MHz.
It is set to 5 MHz (see LO2 in FIG. 2).

Therefore, the frequency of the second local oscillation circuit 11 is 44 MHz higher than 1257.5 MHz.
The lower frequency 1213.5 MHz is an image frequency for the first intermediate frequency signal IF1 (IM in FIG. 2).
G). Therefore, when a television signal of another channel, that is, an image signal exists near the image frequency IMG, the image signal is converted by the second frequency conversion circuit 9 into the second intermediate frequency signal IF2. It is output as the same frequency and is disturbed. Therefore, a dielectric filter, which is a bandpass filter having a sharp selectivity characteristic, is used as the bandpass filter 6 in order to attenuate the level of the image signal as much as possible. In addition, the image frequency is further attenuated by the trap circuit 8.

The trap circuit 8 comprises a series resonance trap circuit comprising an inductor 12 and a capacitor 13 connected in series to each other, and is connected between a signal transmission path and the ground. As the inductor 12, a coil wound with a conductive wire or the like is used. And this trap circuit 8
, Ie, the series resonance frequency is about 8 MHz lower than the oscillation frequency of the second local oscillation circuit 11 that is 447.5 MHz lower than 1257.5 MHz, that is, the center frequency of the band-pass filter 6 is 1301.5 MHz.
The frequency is set to 1213.5 MHz, which is 8 MHz lower.

In the present invention, the trap circuit 8
Is provided between the amplification circuit 7 and the second frequency conversion circuit 9 so that the amplification circuit 7 is interposed between the band pass filter 6 and the trap circuit 8, and the trap circuit 8 is directly connected to the band pass filter 6. It is not connected. Therefore, the signal transmission path between the amplifier circuit 7 and the second frequency conversion circuit 9 has a relatively high impedance without lowering the impedance even at the image frequency. When the circuit 8 is a series resonance type trap circuit, the trap frequency can be greatly attenuated. Moreover, in the series resonance type trap circuit 8, as the inductance of the inductor 12 increases, the resonance Q
Becomes large, so that a large attenuation can be obtained. In the present invention, good attenuation was obtained when the inductance of the inductor 12 was approximately 10 nH (nanohenry) and the capacitance value of the capacitor 13 was approximately 2 pH (picofarad). In addition, the larger the inductance, the more the inductor 12 can be composed of, for example, a coil having a conductive wire wound thereon, so that the trap frequency can be easily adjusted. However, since the capacitance value of the capacitor 13 is relatively small, the inductance of the inductor 12 is about 20 nanohenries in consideration of the easily available minimum capacitance value of about 1 pF. Further, although the trap circuit 8 is provided on the output side of the amplifier circuit 7, the impedance of the trap circuit 8 is generally higher than that of the input side, so that the trap can be greatly attenuated.

FIG. 3 is a block diagram showing a modified example of the double conversion tuner shown in FIG. 1. The position of the band-pass filter 6 and the position of the trap circuit 8 in FIG. 1 are reversed in FIG. ing. That is, in the example of FIG. 3, the trap circuit 8 and the amplifier circuit 7 are provided between the first frequency conversion circuit 3 and the band-pass filter 6, but the trap circuit 8 includes the first frequency conversion circuit 3 and the amplifier circuit. 7 is provided. Therefore, the amplifier circuit 7 is provided between the trap circuit 8 and the band pass filter. Also in this example, since the trap circuit 8 is not directly connected to the band pass filter 6 but is provided between the amplifier circuit 7 and the first frequency conversion circuit 3, the double conversion tuner of FIG. Similarly, the trap circuit 8 is provided in a signal transmission path having a relatively large impedance, and the inductance of the inductor 12 of the trap circuit 8 can be increased.

[0024]

As described above, the double converter according to the present invention is used.
In the John Tuner, a trap circuit is provided between the first frequency conversion circuit and the second frequency conversion circuit, and the image signal corresponding to the first intermediate frequency signal is attenuated by the trap circuit. Image interference generated by the second frequency conversion circuit can be removed, and a tuner suitable for digital CATV reception or DTV television reception can be obtained.

Further, the double conversion tuner of the present invention provides a band which passes a desired signal from the first intermediate frequency signal between the first frequency conversion circuit and the second frequency conversion circuit. Since the pass filter is inserted in series with the trap circuit, an amplifier circuit is provided between the trap circuit and the band pass filter, and the trap circuit is configured by a series resonance circuit of an inductor and a capacitor, the trap circuit is relatively in impedance. -It is provided in a signal path having a high dance, so that by increasing the inductance of the inductor of the trap circuit, a large attenuation can be obtained and the adjustment of the inductance becomes easy.

Also, in the double conversion tuner of the present invention, the trap circuit is provided between the amplifier circuit and the second frequency conversion circuit, so that the trap circuit is a high impedance amplifier circuit. This means that the trap circuit is provided on the output side, so that a larger amount of attenuation of the trap circuit can be obtained.

Further, in the double conversion tuner of the present invention, since the band-pass filter is constituted by a dielectric band-pass filter comprising a dielectric resonator, a channel other than a desired channel including an adjacent channel is used. The level of a television signal can be greatly attenuated. Therefore, the image signal at the image frequency can be greatly attenuated.

Further, in the double conversion tuner of the present invention, since the inductance of the inductor is set to about 10 nanohenries or more, the inductor can be constituted by, for example, a coil wound with a conductive wire. In addition, the adjustment of the trap frequency is further facilitated.

[Brief description of the drawings]

FIG. 1 is a block diagram of a double conversion tuner of the present invention.

FIG. 2 is a diagram showing a state of frequency conversion in a double conversion tuner of the present invention.

FIG. 3 is a block diagram showing a modified example of the double conversion tuner of the present invention.

FIG. 4 is a block diagram of a conventional double conversion tuner.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Input terminal 2 Band pass filter 3 First frequency conversion circuit 4 First mixing circuit 5 First local oscillation circuit 6 Band pass filter 7 First intermediate frequency amplification circuit 8 Trap circuit 9 Second frequency conversion circuit 10 Inductor DESCRIPTION OF SYMBOLS 11 Capacitor 12 2nd mixing circuit 13 2nd local oscillation circuit

Claims (5)

[Claims] 1. A first frequency conversion circuit for converting the frequency of a received signal into a first intermediate frequency signal, and a second frequency conversion circuit for converting the frequency of the first intermediate frequency signal into a second intermediate frequency signal A trap circuit is provided between the first frequency conversion circuit and the second frequency conversion circuit, and the trap circuit attenuates an image signal corresponding to the first intermediate frequency signal. A double conversion tuner characterized in that: 2. A band-pass filter that passes a desired signal from the first intermediate frequency signal is connected in series with the trap circuit between the first frequency conversion circuit and the second frequency conversion circuit. And an amplification circuit is provided between the trap circuit and the bandpass filter,
2. The double conversion tuner according to claim 1, wherein said trap circuit is constituted by a series resonance circuit of an inductor and a capacitor. 3. The double conversion tuner according to claim 2, wherein said trap circuit is provided between said amplifier circuit and said second frequency conversion circuit. 4. The double conversion tuner according to claim 2, wherein said band pass filter is constituted by a dielectric band pass filter comprising a dielectric resonator. 5. The method according to claim 2, wherein said inductor has an inductance of about 10 nanohenries or more.
Or the double conversion tube described in 3 or 4 above.
Na.